Exceptional thermal stability and enhanced hardness in a nanostructured Mg-Gd-Y-Zn-Zr alloy processed by high pressure torsion
Exceptional thermal stability and enhanced hardness in a nanostructured Mg-Gd-Y-Zn-Zr alloy processed by high pressure torsion
A Mg-8.2Gd-3.8Y-1.0Zn-0.4Zr (wt.%) alloy is processed by solution treatment and high pressure torsion (HPT) at room temperature to produce a nanostructured light material with high hardness. The stability of this alloy is subsequently tested through isochronal annealing for 0.5 h at 373 K to 673 K. The results reveal a thermal stability that is vastly superior to that of conventional Mg-based alloys processed by severe plastic deformation: the grain size remains at around 50 nm on heating to 573 K, and as the temperature is increased to 673 K, grain growth is restricted to within 500 nm. The stability of grain refinement of the present alloy/processing combination allowing grain size to be limited to 55 nm after exposure at 573 K, appears to be nearly one order of magnitude better than for the other SPD processed Mg-RE type alloys, and 2 orders of magnitude better than those of SPD processed RE-free Mg alloys. This superior thermal stability is attributed to formation of co-clusters near and segregation at grain boundaries, which cause a thermodynamic stabilization of grain size, as well as formation of β-Mg
5RE equilibrium phase at grain boundaries, which impede grain growth by the Zener pinning effect. The hardness of the nanostructured Mg-Gd-Y-Zn-Zr alloy increases with increasing annealing temperature up to 573 K, which is quite different from the other SPD-processed Mg-based alloys. The high hardness of 136 HV after annealing at 573 K is mainly due to solute segregation and solute clustering at or near grain boundaries.
Grain growth, High pressure torsion, Mg-RE alloy, Phase transformation, Solute segregation, Thermal stability
Sun, Wanting
67cb2890-35df-4982-adec-16c01d9b6e76
He, Yang
026e4277-e03a-4ad5-bf7e-3253c36c58bf
Qiao, Xiaoguang
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Zhao, Xiaojun
bec2210d-8b68-47c2-b978-953b71a13110
Chen, Houwen
2568dd69-4a29-4992-a140-b1db16e9cfd0
Gao, Nong
9c1370f7-f4a9-4109-8a3a-4089b3baec21
Starink, Marco
fe61a323-4e0c-49c7-91f0-4450e1ec1e51
Zheng, Mingyi
2f368112-58de-4ed1-9773-19e31d03e667
6 June 2022
Sun, Wanting
67cb2890-35df-4982-adec-16c01d9b6e76
He, Yang
026e4277-e03a-4ad5-bf7e-3253c36c58bf
Qiao, Xiaoguang
d66f41b7-eac1-4875-8164-ee44a2a09074
Zhao, Xiaojun
bec2210d-8b68-47c2-b978-953b71a13110
Chen, Houwen
2568dd69-4a29-4992-a140-b1db16e9cfd0
Gao, Nong
9c1370f7-f4a9-4109-8a3a-4089b3baec21
Starink, Marco
fe61a323-4e0c-49c7-91f0-4450e1ec1e51
Zheng, Mingyi
2f368112-58de-4ed1-9773-19e31d03e667
Sun, Wanting, He, Yang, Qiao, Xiaoguang, Zhao, Xiaojun, Chen, Houwen, Gao, Nong, Starink, Marco and Zheng, Mingyi
(2022)
Exceptional thermal stability and enhanced hardness in a nanostructured Mg-Gd-Y-Zn-Zr alloy processed by high pressure torsion.
Journal of Magnesium and Alloys.
(doi:10.1016/j.jma.2022.04.003).
Abstract
A Mg-8.2Gd-3.8Y-1.0Zn-0.4Zr (wt.%) alloy is processed by solution treatment and high pressure torsion (HPT) at room temperature to produce a nanostructured light material with high hardness. The stability of this alloy is subsequently tested through isochronal annealing for 0.5 h at 373 K to 673 K. The results reveal a thermal stability that is vastly superior to that of conventional Mg-based alloys processed by severe plastic deformation: the grain size remains at around 50 nm on heating to 573 K, and as the temperature is increased to 673 K, grain growth is restricted to within 500 nm. The stability of grain refinement of the present alloy/processing combination allowing grain size to be limited to 55 nm after exposure at 573 K, appears to be nearly one order of magnitude better than for the other SPD processed Mg-RE type alloys, and 2 orders of magnitude better than those of SPD processed RE-free Mg alloys. This superior thermal stability is attributed to formation of co-clusters near and segregation at grain boundaries, which cause a thermodynamic stabilization of grain size, as well as formation of β-Mg
5RE equilibrium phase at grain boundaries, which impede grain growth by the Zener pinning effect. The hardness of the nanostructured Mg-Gd-Y-Zn-Zr alloy increases with increasing annealing temperature up to 573 K, which is quite different from the other SPD-processed Mg-based alloys. The high hardness of 136 HV after annealing at 573 K is mainly due to solute segregation and solute clustering at or near grain boundaries.
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1-s2.0-S2213956722001013-main
- Version of Record
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1-W Sun- Journal of Magnesium and Alloys
- Version of Record
More information
Accepted/In Press date: 17 April 2022
Published date: 6 June 2022
Additional Information:
Funding Information:
This work was supported by National Natural Science Foundation of China (No. U21A2047 and 51971076 ), China Postdoctoral Science Foundation (Grant No. 2019M653599 ) and Guangdong Basic and Applied Basic Research Foundation (No. 2019A1515110289).
Publisher Copyright:
© 2022
Keywords:
Grain growth, High pressure torsion, Mg-RE alloy, Phase transformation, Solute segregation, Thermal stability
Identifiers
Local EPrints ID: 468330
URI: http://eprints.soton.ac.uk/id/eprint/468330
ISSN: 2213-9567
PURE UUID: 566de79b-c2eb-423e-8ee5-2be416681c3e
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Date deposited: 10 Aug 2022 18:10
Last modified: 17 Mar 2024 02:53
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Contributors
Author:
Wanting Sun
Author:
Yang He
Author:
Xiaoguang Qiao
Author:
Xiaojun Zhao
Author:
Houwen Chen
Author:
Mingyi Zheng
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